JPH0258815A - Manufacture of ceramic electronic component - Google Patents

Abstract

PURPOSE:To provide an electrode-buried green sheet which can be laminated very easily and with high precision, by printing an electrode ink containing ultraviolet-curing resin on a substrate, applying ultraviolet rays thereto to cure the parts of the electrode ink not in contact with the substrate, applying ceramic slurry thereon and drying the same to provide the electrode-buried ceramic green sheet. CONSTITUTION:Electrode ink 2 containing ultraviolet-curing resin is printed on a substrate 1, and ultraviolet rays 3 are applied to the electrode ink 2 without passing through the substrate 1 so that only the parts of the electrode ink 2 not in contact with the substrate 1 are cured while the parts in contact with the substrate 1 are uncured or semicured. Ceramic slurry 4 is applied on the substrate 1 thus provided with an electrode ink film 2a, and is dried to provide an electrode buried ceramic green sheet 5 on the substrate 1. The ceramic green sheet 5 is thermocompression bonded to another ceramic green sheet or other electrode without peeling it off from the substrate 1, and then the substrate 1 only is peeled off. Consequently, the electrode-buried ceramic green sheet 5 is transferred to said another ceramic green sheet or other electrode.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a method for manufacturing multilayer ceramic electronic components such as multilayer ceramic capacitors, which are widely used in electrical products such as video tape recorders and liquid crystal televisions, particularly by a transfer method. In addition, the present invention can be widely used in manufacturing multilayer ceramic electronic components such as multilayer ceramic substrates, multilayer varistors, and multilayer piezoelectric elements.

Conventional Technology Taking a multilayer ceramic capacitor as an example, its internal electrodes are usually formed by screen printing electrode ink on ceramic green sheets to be laminated later. . Here, the electrode ink contains, in addition to metal particles serving as the internal electrodes, a binder consisting of a face and a solvent for dissolving it.

However, forming internal electrodes by the printing method has the following problems.

First, the solvent contained in the binder in the electrode ink has a tendency to seep into the raw ceramic sheet. When the raw ceramic sheet is thinned to, for example, about 5 microns, the binder containing the electrode metal tends to penetrate into the printed surface. In some cases, the molten metal penetrates into the back side of the capacitor, resulting in a decrease in voltage resistance of the obtained multilayer ceramic capacitor. In addition, when using the printing method, bleeding inevitably occurs in the periphery of the electrode ink film formed in a predetermined pattern, making it difficult to improve the accuracy of the dimensions and shape of the internal electrodes of the obtained multilayer ceramic capacitor. There wasn't.

Furthermore, when forming a plurality of arranged electrode ink films on a single raw ceramic sheet by a printing method, in particular,
Near the end of the squeegee movement range, there was a tendency for the spacing between adjacent electrode ink films to become slightly larger than the set value. This also leads to a decrease in the dimensional accuracy of the internal electrodes of the obtained multilayer ceramic capacitor.

A transfer method has been considered as a method that can eliminate the drawbacks of the printing method as described above.

In this transfer method, an electrode ink film is formed on a suitable carrier film, and then heated and dried to drive off the solvent, and then an electrode film to become an internal electrode is formed on a green ceramic sheet. However, the above-described transfer method still has problems that need to be solved. First, it was difficult to transfer the electrode ink unless it was sufficiently dried on the carrier film. Moreover, even if the electrode ink was sufficiently dried, it was not completely transferred and even became mottled. Such incomplete transfer causes variations in the capacitance of the obtained multilayer ceramic capacitor.

Furthermore, in order to sufficiently heat and dry the electrode ink,
It took a long time.

As mentioned above, in the case of the transfer method, there are various problems, but also in the case of the printing method mentioned earlier, the use of a solvent-dissolved adhesive as a binder for the electrode ink causes various problems. It can be seen that this is the factor causing this.

Conventionally, several approaches have been taken to address this problem.

For example, as disclosed in Japanese Patent Application Laid-Open No. 56-106244, there is a method in which only electrodes are first printed on a base film, and then a raw ceramic sheet is formed thereon by a casting method. In addition, as in Japanese Patent Publication No. 40-19975, an unfired ceramic thin film with electrodes can be produced by applying an electrode paint, drying it, continuously applying a dielectric slurry, and peeling this off from the support. There is a way to get it.

However, since the electrode-embedded ceramic raw sheets made by these methods are peeled from the base film, when the film thickness becomes thinner, the mechanical strength is extremely reduced, so that they can no longer be handled by themselves. .

For this reason, it was not possible to make the layer thinner than 20 microns.

Furthermore, the following methods are also being considered. First of all, in JP-A-62-EA413, for ease of handling,
While the raw ceramic sheet is attached to the base film,
Electrode ink is printed on the surface of this raw ceramic sheet,
A method has been proposed in which the base film is peeled off after lamination. However, if we consider the erosion of the green ceramic sheet by the electrode ink in this method, we will find that the thinner the ceramic green sheet becomes, the more easily it will be eroded by the electrode ink. Furthermore, the electrode ink solvent soaked into the green ceramic sheet can evaporate from the opposite side of the green ceramic sheet (the side on which the electrode ink is not printed) because it is covered with the base film. It disappears and remains inside the raw ceramic sheet. However, the electrode ink remains on the green ceramic sheet for a longer time than in the past, and the green ceramic sheet is more likely to be attacked by the electrode ink.

Next, JP-A-63-31104 and JP-A-63-
In JP 32909, an electrode ink film is formed on a ceramic green sheet by thermally transferring the electrode ink instead of printing it on the surface of the ceramic green sheet while preventing the adverse effects of the electrode ink's solvent. Methods have been proposed to increase the yield of multilayer ceramic capacitors. However, in this method, both the ceramic green sheets and the electrodes are alternately laminated by thermal transfer. If the number of laminated layers of the pick and internal electrodes is, for example, 50, thermal transfer is repeated at least 5 times for laminating raw ceramic sheets, 60 times for laminating electrodes, and at least 100 times in total. However, if there is only one layer of green ceramic sheet, there is a high possibility that pinholes will occur. In order to increase the yield rate, continuous two-layer transfer of ceramic raw sheets can be considered. However, in this case, at least a total of 150
Thermal transfer is repeated more than once.

This results in different thermal histories for each transferred layer. That is, the first thermally transferred layer is then 16
Thermal history is added nearly 0 times. On the other hand, the last stacked layers are only subjected to several subsequent thermal cycles. Generally, each time such a thermal history is applied, the green ceramic sheet is thermally deformed little by little. moreover,
If the layer that is thermally transferred first has a large thermal history, the deformation will be larger than the layer that is laminated last. Therefore, the green ceramic sheet may be deformed, the thickness may change, the area of the electrode may change, the laminated position of the electrode may be shifted, and defects may occur during cutting after lamination.

However, in JP-A No. 63-51616, electrodes in a predetermined pattern are provided on one side of the film, and the film with the dried electrodes is placed on a raw ceramic sheet so that the electrodes overlap. A method of manufacturing a multilayer capacitor has been proposed in which the capacitor is thermally transferred onto a ceramic green sheet, a plurality of the ceramic green sheets are stacked, and then fired. However, this method requires thermal transfer of the electrodes before the thermal lamination of the ceramic green sheets, and the p1 ceramic green sheets are subject to thermal history, resulting in poor accuracy. However, the electrodes are thermally transferred not onto the dimensionally rigid base film, but after being thermally transferred onto the heat-softening ceramic green sheet. At this time, there is a high possibility that not only the raw ceramic sheet but also the base film will undergo thermal transfer during electrode transfer, and in this case, the lamination accuracy will further deteriorate.

Unfortunately, in this method, it is essential to use a base film with excellent heat resistance, which increases manufacturing costs.

Furthermore, in Japanese Patent Application Laid-Open No. 63-51617, the electrodes are transferred by heating and pressing a film onto a green ceramic sheet using a pressing die equipped with protrusions that match the electrode pattern, and transferring a predetermined pattern of electrodes from the electrode layer to the ceramic sheet. A method of transferring to a raw sheet is used.

However, in this case, if a protrusion is used, the thickness of the green ceramic sheet at that portion inevitably changes. Furthermore, as many protrusions as the number of electrodes are required, the pressure at each protrusion inevitably varies. For this reason, the thickness or compressibility of the ceramic raw sheet at each electrode position varies. In addition, there is a pressure distribution even at the protrusion where one electrode is transferred (this is a phenomenon generally called marginal zone, which is the cause of uneven ink density in letterpress printing), and the thickness of the raw ceramic sheet will change. Furthermore, both the ceramic raw sheet itself and the base film on which the ceramic raw sheet is formed are susceptible to irregular deformation because they are partially subjected to thermal pressure before lamination. Also,
As in the case of JP-A-63-51616, after the electrodes are thermally transferred not onto a dimensionally rigid base film but onto a heat-softening green ceramic sheet,
It will be thermally transferred. At this time, not only the raw ceramic sheet but also the base film is thermally deformed during the thermal transfer of Ti, which deteriorates the lamination accuracy. For this reason,
It becomes essential to use a base film with excellent heat resistance, which poses a problem of increasing manufacturing costs.

In addition, as a method for manufacturing multilayer ceramic capacitors by embedding electrodes in raw ceramic sheets,
There are methods proposed in Japanese Patent Publication No. 24225 and Japanese Patent Publication No. 56-37619.

However, in these manufacturing methods, multiple layers of dielectrics and electrodes are alternately printed and laminated on one base film using a method such as gravure printing. Therefore, there is a problem in that the ceramic raw sheet is attacked by the solvent contained in the stain electrode.

The method proposed in Japanese Patent Publication No. 59-172711 is to embed electrodes formed on a base film in a raw ceramic sheet, to laminate the base film together, and to sinter it to produce a multilayer ceramic capacitor. However, in order to bake the base film together, it is necessary to use a very thin base film with a thickness of about 1.6 to 14 microns. Additionally, the amount of base film fired increases in proportion to the number of laminated layers.
Delamination is more likely to occur. For this reason, the base film needs to be made thinner as the number of layers increases. Furthermore, base films made of resins that are easily fired have poor mechanical strength. Unfortunately, this lamination method cannot withstand use in automatic lamination equipment or the like.

In addition, as a transfer method that can be carried out without using the solvent that causes the problem, as in Japanese Patent Application Laid-Open No. 63-53912, a film of electrode paste that becomes the internal electrode containing an ultraviolet curable resin is made to be ultraviolet-transparent. The electrode paste is formed on a carrier film, and the electrode paste is irradiated with ultraviolet rays through the carrier film to cure the ultraviolet curable resin on the side of the electrode paste film that is in contact with the carrier film, and the ultraviolet curable resin on the other side. There is a method for forming internal electrodes of a ceramic laminate in which the ultraviolet curable resin is kept in an uncured or semi-cured state and the electrode paste is transferred and laminated onto a green ceramic sheet. However, with this method,
The electrode ink is cured only on the carrier film side, and the surface side of the electrode ink (the side other than the carrier film) is uncured or semi-cured and has adhesive properties. This so-called half-dry electrode ink surface is difficult to handle, as even small amounts of dirt and grime tend to adhere to it. Further, after printing the electrode ink, the surface is half dry, so the carrier film cannot be rolled up. Furthermore, after transferring the electrode paste to the green ceramic sheet, the green ceramic sheet is laminated without being held by a carrier film. Therefore, when the thickness of the green ceramic sheet becomes less than about 20 microns, the mechanical strength of the green ceramic sheet itself becomes insufficient and it becomes impossible to handle it. For this reason, there is a limit to how thin the raw ceramic sheet can be made to be.

Problems to be Solved by the Invention Therefore, in the manufacturing method of multilayer ceramic capacitors as described above, it is difficult to prevent the adverse effects of electrode ink.Furthermore, it is difficult to prevent the negative effects of electrode ink from producing multilayer ceramic capacitors that avoid the effects of the solvent of N electrode ink. In the conventional method, accurate lamination could not be achieved.In order to prevent the influence of the solvent in the electrode ink, when electrodes are formed on a green ceramic sheet by thermal transfer, the ceramic green sheet itself is exposed to heat. Transformation.

There is a limit to increasing the number of laminated layers because it is easy to heat and undergoes a complex thermal history multiple times or more.

Furthermore, simply embedding electrodes in a raw ceramic sheet makes it difficult to handle the raw ceramic sheet when it becomes thin, and there is a limit to how thin the raw ceramic sheet can be.

The present invention solves the above problems by having the surface of the electrode ink (the side not in contact with the base film) hardened, thereby making it possible to easily embed the electrode ink inside the raw ceramic sheet. (Because the surface in contact with the base film is uncured), it can stick to the base film due to its adhesive strength.Furthermore, this electrode-embedded ceramic raw sheet is thermally transferred to the surface of another ceramic raw laminate, etc., and the base film is When the electrode ink is peeled off, an uncured portion with the adhesiveness of the electrode ink appears on the surface, thereby providing a manufacturing method that facilitates the lamination of raw ceramic sheets and the like.

Means for Solving the Problems In order to solve the above problems, the method for manufacturing a ceramic electronic component of the present invention includes printing an electrode ink containing an ultraviolet curable resin on a support, and then applying the support to the electrode ink. The ultraviolet rays are irradiated without passing through the electrode ink, so that only the portion of the electrode ink that is not in contact with the support is cured, and the portion of the electrode ink that is in contact with the support remains uncured or semi-cured. After curing the electrode ink, a ceramic slurry is applied to the mJ marking support provided with the electrode ink film, and then the ceramic slurry is dried to create a green ceramic sheet with electrodes embedded on the support. Next, the electrode-embedded ceramic green sheet is thermocompressed onto another ceramic green sheet or another electrode without peeling off the support, and then only the support is peeled off, and the electrode-embedded ceramic This device has a configuration in which the green sheet is transferred onto the other ceramic green sheet or another electrode.

Effect of the present invention With the above-described structure, since the electrode is dried, it is possible to prevent the adverse effects of the electrode ink, and the surface of the electrode ink (the side not facing the base film) is hardened. Additionally, when producing a green ceramic sheet with embedded electrodes, it is less susceptible to the effects of the solvent contained in the ceramic slurry.

Further, according to the present invention, by using an ultraviolet curable resin having an appropriate viscosity, metal particles can be made into a paste without using any phenol or solvent. Therefore, the problems that occurred in the prior art described above were caused by the printing method or the solvent, so it is possible to eliminate all of these problems.

That is, basically, since the electrodes are embedded in the raw ceramic sheet, the electrodes can be laminated and the ceramic raw sheets can be laminated at the same time. Further, since the raw ceramic sheet with embedded electrodes is handled while being held by the support until the lamination is completed, each layer can be laminated with great ease and accuracy.

Then, the electrode ink can be dried simply by irradiating it with ultraviolet light. In addition, UV irradiation is performed from the non-base film side without passing through the base film with the electrode ink formed on the base film, so the UV-curable resin on the side of the electrode ink that is not in contact with the base film is cured. When the ceramic slurry is applied, the UV-curable resin on the side that contacts the base film remains uncured or semi-cured.
It still has adhesive strength, so when this electrode-embedded raw ceramic sheet is transferred and the base film is peeled off, this adhesive surface appears on the surface, making it easier to transfer the next ceramic raw sheet, etc. becomes.

Furthermore, in the present invention, since there is no need to use any solvent in the electrode ink, there is no occurrence of pollution caused by the solvent.

Embodiment FIGS. 2 to 5 sequentially illustrate each step of preparing a green ceramic sheet with embedded electrodes on a support included in one embodiment of the present invention.

First, 'tr!' is made by mixing metal particles and ultraviolet curing resin, which will become the internal electrodes. w ink is prepared. Here, although the ultraviolet curable resin is liquid, it has a suitable viscosity, and can be made into an ink-like state by itself.

Next, as shown in FIG. 2, a base film 1 is prepared, and an electrode ink 2 is formed on the base film 1 in a predetermined pattern using the electrode ink that has been removed by a method such as printing.

Next, as shown in FIG. 3, the electrode ink 2 is irradiated with ultraviolet a3 without passing through the base film 1. At this time, as shown schematically in FIG. 6, the ultraviolet rays 3 are reflected from the surface of the metal particles 9 included in the electrode ink 2 in the direction of the arrow and pass through the ultraviolet curable resin 10.
The degree to which the ultraviolet rays 3 reach the lower surface of the electrode ink 2 as shown in the figure decreases. Therefore, as shown schematically in FIG. 7, when viewed in the thickness direction of the cured electrode ink film 2JL, the electrode ink film 2a typically consists of a hardened layer 11 and an unhardened or semi-hardened layer. It is divided into 12 parts.

Generally used ultraviolet curable resins are produced by radical polymerization or ionic polymerization (cationic polymerization, etc.), and the polymerized cured layer 11 is then formed even if the solvent contained in the ceramic slurry is organic. It will not re-dissolve. In particular, it is better to use a radical polymerization type because cationic polymerization types tend to generate nitrogen as a by-product at the start of polymerization. Further, types of resin include unsaturated polyester type, acrylic type, thiol/ene type, etc. Furthermore, the curing speed can be increased by irradiating ultraviolet rays in a nitrogen atmosphere or the like.

Next, as shown in FIG. 4, the electrode ink film 2a is embedded with a ceramic slurry 4.

At this time, like the hardened layer 11 in FIG. 7, the electrode ink film 2a
Since the surface of the electrode ink film 2 is hardened, the solvent contained in the ceramic slurry 4 causes the electrode ink film 2 to harden.
A will not be affected or dissolved. Here, the method of applying the ceramic slurry 4 is preferably one that does not cause damage to the electrode ink film 2a. in particular,
A gravure coating device, an applicator coating device, etc. that do not use an impression cylinder can be used. Moreover, even if a printing method such as a screen printing method is used, it can be easily and effectively carried out by printing the ceramic slurry 4 without patterning (that is, in a peta pattern).

Next, as shown in FIG. 6, the electrode ink film 2a is embedded in the green ceramic sheet 6. Here, the ceramic raw sheet 6 is made by drying the ceramic slurry 4 shown in FIG. 4. By doing so, the electrode ink film 2a can be embedded inside the green ceramic sheet 5 without causing unevenness on the surface of the green ceramic sheet 6.

Next, a manufacturing method and a laminating method of a multilayer ceramic capacitor according to an embodiment of the present invention will be explained using FIG. In FIG. 1, 6 is a press, 7 is a heater>8 is a stand, and the press 6 is heated to a constant temperature by the heater 7. First, as shown in FIG. 5, the electrode-embedded ceramic green sheet is made up of one side of the base film on the side of the press 6, the ceramic green sheet 5a fixed on the table 8, and the electrodes as shown in FIG. Six ceramic raw sheets are each set on the side of the ceramic raw laminate made of the ink film 2b. Next, the press 6 heated to a constant temperature by the heater 7 moves up and down as shown by the arrow, and the electrode ink film 2a and the ceramic green sheet 6a are coated on the surface of the ceramic green laminate including the electrode ink film 2b and the ceramic green sheet 6a. Transfer sheet 6. Moreover, in this way, the electrode ink film 21L and the green ceramic sheet 5 are transferred to form the electrode ink film 2b and the green ceramic sheet 5a. In this way, in the present invention, the electrode ink film 2
By not peeling off the base film 1 and the raw ceramic sheet 5, the raw ceramic sheet 5 can be handled while maintaining its strength. is not included, which reduces the problems that occur during firing. Also,
The electrode ink film 2a on the surface from which the base film 1 has been peeled off is in an uncured but semi-cured state and has adhesive properties on the surface. As a result, the green ceramic sheet or the like to be transferred next becomes more easily transferred.

In addition to resin films such as polyester, it is also possible to selectively harden, semi-cure or uncure the electrode ink film by using a support that does not transmit ultraviolet light and has a metal thin film formed thereon. I can do seven.

Furthermore, the manufacturing method of the present invention can be applied not only to the multilayer ceramic capacitors described in the above embodiments but also to other multilayer ceramic electronic components such as multilayer ceramic substrates and multilayer varistors.

Although the invention has been described above in connection with the illustrated embodiments, several modifications are possible within the scope of the invention.

Effects of the Invention As described above, the present invention includes printing an electrode ink containing an ultraviolet curable resin on a support, and then irradiating the electrode ink with ultraviolet light without passing through the support. After the electrode ink is cured so that only the part that is not in contact with the body is cured, and the part of the electrode ink that is in contact with the support remains uncured or semi-cured, the electrode ink film is provided. A ceramic slurry is applied onto the support, and then the ceramic slurry is dried to produce a green ceramic sheet with embedded electrodes on the support, and then the green ceramic sheet with embedded electrodes is peeled off from the support. After heat-compression bonding onto another ceramic raw sheet or other electrode without removing the material, only the support is peeled off, and the electrode-embedded ceramic raw sheet is transferred onto the other ceramic raw sheet or other electrode. By doing this, the electrodes are dried, which prevents the adverse effects of the solvent contained in the electrode ink, and the green ceramic sheet can be fixed to the support with the electrodes embedded in it and handled, reducing damage and dimensional accuracy. Good too. Also,
Because the electrode ink is embedded in the raw ceramic sheet, T! Irregularities caused by the L pole are also less likely to occur. Furthermore, since the surface of the N electrode ink film is hardened, it is less susceptible to the adverse effects of the solvent contained in the slurry when embedding the electrode ink film. In addition, when this electrode ink film is embedded in the ceramic green sheet and is transferred along with the support onto another ceramic green sheet, etc., and when the support is peeled off, the electrode ink film is transferred to the base film side (toe). Since the surface (exposed on the surface) is semi-cured or uncured, it has adhesive properties and can assist in the transfer of the next green ceramic sheet, etc.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view for explaining the manufacturing method of a multilayer ceramic capacitor according to an embodiment of the present invention, and FIGS. 6 is an enlarged sectional view showing a model of how ultraviolet rays pass through the electrode ink film in the step of FIG. 3, and FIG. 7 is a cross-sectional view of the step of manufacturing the sheet. FIG. 2 is a cross-sectional view schematically explaining the electrode ink film obtained as a result. 1...Base film, 2...71 ink, 2a, 2b...electrode ink film, 3...
...Ultraviolet light, 4...Ceramics slurry,
5.5a...Ceramic raw sheet, 6...
・Press, completed...Heater, 8...stand, 9...
・Metal particles, 10... Ultraviolet curing resin, 11.
...Hardened layer, 12...Uncured or semi-cured layer. Name of agent: Patent attorney Shigetaka Awano and 1 other person
figure! -・ 2a, 2b 5.54 -m- Base film electrode ink ceramic raw sheet Press machine stand 1- Base film 2-t fi (Tsuki? 1-Denya Itsuki 3-Haigaiori

Claims (2)

[Claims] (1) After printing an electrode ink containing an ultraviolet curable resin on a support, the electrode ink is irradiated with ultraviolet rays without passing through the support, and only the portions of the electrode ink that are not in contact with the support are cured. After curing the electrode ink so that the part of the electrode ink in contact with the support remains unhardened or semi-hardened, a ceramic film is applied on the support provided with the electrode ink film. A slurry is applied, and then the ceramic slurry is dried to produce an electrode-embedded ceramic raw sheet on the support, and then another ceramic raw sheet is coated without peeling the electrode-embedded ceramic raw sheet from the support. Or, a ceramic electronic component characterized in that after thermocompression bonding onto another electrode, only the support is peeled off, and the electrode-embedded ceramic raw sheet is transferred onto the other ceramic raw sheet or another electrode. manufacturing method. (2) The method for manufacturing a multilayer ceramic electronic component according to claim 1, wherein the support is not transparent to ultraviolet rays.